Carriage control mechanism



Feb. 9, 19143.A R. E HART `2,310,430

CARRIAGE CONTROL MEGHANISM Filed May 2, 1941 4 Sheets-Sheet 2 ATTORNEY Feb, 9, 1943. Rf-E. HART 2,310,430

CARRIAGE' CONTROL MECHANISM Filed May 2, 1941 4 sheets-sheet 5' FE1-4- 73% U 73, {T- 29 u ATTORNEY Feb. 9, 1943. R; E. HARTY 2,310,430

yCARRIAGE CONTROL MECHANISM f Filed May 2, 1941 I Sheets-Sheet 4 lIlllllllllIIlll//lllllll INVENTOR: K

ATTORNEY.

Patented Feb. 9, i943.

anais@ 2,310,430 CARREGE CONTROL MECHANISM Robert E. Hart, Poughkeepsie, N. Y., assignor to International Business; Machines Corporation, New York, N. Y., a corporation ot New York Application May 2, mi, serial No. 391,494

29 claims. (ci. 1oz-c7) This invention relates to carriage v. control mechanisms and, more particularly, to pneumatic drive mechanisms for carriages of typewriting and punching machines and the like.

The general object of the instant invention resides in the provision of pneumatic drive means of .improved construction and yarrange- -ment for operating the carriage during normal spacing operations and also to provide automatic control during certain functional movements such as tabular spacing, eject and carriage return.

More specifically, the object of the invention is to provide a carriage'mounted on a movable hollow cylinder which is displaced back and forth along a stationary piston by means of regulated air or other iiuid pressure.

Another specific object is the provision of a needle valve inthe air system and control means thereforI for controlling the air pressurel automatically during certain functions such as tabular spacing, carriage return and ejecting operations to govern the speed lof movement of the carriage during these operations.

An additional objectis to provide a pump of high efiiciency and simple construction to maintain the air pressure in the system at the proper value for smooth operation of the carriage in either direction. This phase of the invention is claimed in my vcopending application Serial No.`

429,497, filed February 4, 1942.

A further object of the invention isthe pro vision of means controlled by the carriage, as it is spaced to its last' column position, for aut.)- matically causing a reversal, in the direction of the air pressure supplied by the pump, to effect a carriage return.

According to the invention, the carriage is mounted on a hollow cylinder which is slidable along a piston under air pressure supplied and maintained by a rotary pump. An escapement mechanism normally holds the carriage in oneA of a plurality of columnar positions, and this Vmechanism isv operated, upon the depression of a character key, to control the normal spacing movement of the carriage from one column to the next. Carriage return is effected under con- ,trol of the carriage itself in that the direction of the air pressure from the pump is automaticallyreversed as the carriage' reachesits last .columnar position. In order that the carriage a needle valve is inserted in the air system to and associated mechanism and the air system` for operating the same.

Fig. la is a detail perspective view of the rack escapement assembly.

Fig. 2 is a side sectional view of a portion of -the operating mechanism of' the machine to which the invention is applied.

Fig. 3 is atop view of a portion of the carriage control mechanism.

Fig. 3a is a detail perspective of part of the mechanism shown in Fig. 3. s

Fig. 4 is a sectional view showing the essential parts of the drive mechanism of the machine.

Figs. 5, 6, .7 and 8 are detail structural views of the pump structure. y

Fig. 9'is a wiring diagram showing the essential circuits for controllingI the carriage movements under vvarious conditions.

Referring now to the drawings, there is shown a portion of the operating mechanism of a machine commonly referred to in the art as a printing punch because of the fact that provision is'made for the punching of holes in a record card accompanied by the interpretation of said holes in printed format the top of the card. vOne embodiment of such a machine is disclosed-and described in detail in United States Patent 2,046,082, issued to A. W. Mills on June 30, 1936. The instant invention will be described presently, by way of example, in connection with e.- machine of this type, and only such parts of the old structure which are deemed necessary to clarify' the description of the-invention will be considered herein. More detailed information as to the various general operations of the ma chine, if desired, may -be obtained by referring to the above mentioned patent.

Briefly, the drive mechanism (Fig.' 4) comprises a power driven shaft 20 which is journaled in bearingI supports 2i and 22'and is rotated by suitable power means continuously in the direction indicated by the arrow. Shaft 20 carries a worm 23 meshing with a gear 24 fastened'on a transverse shaft 25 which will hereafter be referred to as the fclutch shaft.. A

spiral gear 28 is secured to shaft 20 and is arranged to mesh with a gear 21 ior the purpose of rotating the vertical shaft 28-and roller 29 fastened to the upper end of shaft 28. Just to the left of the bearing support 22, the shaft 28 is enlarged and carries aworm 30 which meshes with gear 3| fastened to a transverse shaft 32. Thus, it is seen that shafts 20, 25, 28, and32 are maintained in continuous rotation as long as the power means is operative. A suitable power means is represented by an electric motor M in the wiring diagram (Fig. 9) where it is shown to be connected directly across the line for continuous operation. The extreme left end of the power driven shaft 28 connects directly with the rotor of an air pump, generally designated 35, which will now be described.

The pump 35 (Figs. 5-8) is of the rotary type comprising a rotor 36 with four equally spaced blades 31 freely mounted in radial slots 38 and biased outwardly by springs 39. Enclosing the rotor 36 is a hardened ground ring 4llV with which the edges of blades 31 engage. Since the pump is maintained in continuous operation through its connection with shaft 28, it is necessary to reduce friction to a minimum to prevent overheating. To accomplish this, the ring 48 is mounted freely on roller bearings 4| so that it may rotate with the blades A finned casing 42 surrounds the parts just described and holds bearings 4| in contact with the outer surface of ring 48. A back plate 43 is provided and is tted to the back of the casing 42. A spacer plate 44 is inserted between the back plate and the casing. Mounted freely within the front end of the casing is a bearing retainer 45, and immediately in front of the bearing retainer and'tted to the front end of thecasing is a front end plate 46.

Plate 46 is a casting of appreciable thickness and is provided -with an intake port 48 anda pressure port 41 vextending in an axial direction through the plate and a pair of outlet ports 48 and 50 extending in a radial direction through the shell of the casting'. A rotatable valve 5| is freely mounted within the casting and is provided with a pair of elongated holes 52 and 53 which are each arranged to' cooperate with one or the other of the ports 41 and 48 to complete air passageways between the latter ports and the outlets 49 and 50. In the position shown, port 41, valve hole 52, and outlet 49 form an air path as do port 48, valve hole 53, and outlet 50. In view of the counterclockwise rotation of the rotor 36, the outlet 48, as shown, is delivering air to the exterior whereas outlet 50 is serving to admit air to the pump. Under normal conditions, however. as explained later, it isdesirable to have the direction of air flow through these outlets reversed.' such reversal being accomplished by a limitedrotation of the valve 5|.

A cover plate 54 is placed in front of valve 5| and is screwed to the front end plate casting 46 so as to form an enclosure lfor the valve. An.

axial stud 55, fastened to valve 5|, extends through the cover plate and has a short bifurcated arm 56 also secured thereto. Movement of arm 56 rocks the stud 55, thereby causing a limited rotation of valve 5|. In order to effect movement of the arm 58 automaticallyl solenoid 51 (Fig. 1) with a plunger 58 is provided. The solenoid is mounted conveniently on an adjacent portion of the frame of the machine. The plunger 58 is connected to a shaft 58 which extends through holes in the back and front end plates, and is bent at substantially a right angle at a point in front of the front cover plate, and is seated in the bifurcatedarm 58. The seated end of shaft 58 is beveled to interit more effectively with arm 56 but, of course, a sufficient clearance must Abe maintained 4to .prevent binding. It will be evident that the attraction of plunger 58 upon energization of solenoid 51 causes a rocking of shaft 59 to move arm 58, and hence valve 5| to the1 position as shown in Fig. 6, to bring about a reversal in the normal direction of the air pressure delivered -by the pump. Solenoid 51 will hereafter -be 'referred to as the pump solenoid.

Referring now to Fig. 1, it will benoted that the outlets 48 and'58 are connected to a closed air system, the air lines for which are supported by side frames 68 and 6| and hollow castings 63 and 85, respectively, carried by the side frames. A hollow rod 66, supported at one end -by an extension of casting 83 and at the other end by casting 85, carries an air cylinder 18 slidably mounted thereon. The air cylinder is part of a carriage assembly which includes a rack 1| (see also Fig. la) and a frame 12. Pivotally mounted at the left and right ends of frame 12, respectively, are record card fingers 13 and 15 which are adapted to hold a record card C of predetermined size. The left card finger 13 is springlbiased toward the right card finger 15 by a coil spring 14, and the right card nger 15 is provided with an adjustable screw 16 which is 'set to obtain accurate alignment of the card with respect to the carriage rack 1|. The record card is divided into vertical columnar positions and the distance from column to column on the card corresponds to the distance between teeth on the rack.A A guide rail 11 is providedfor the carriage yframe 12 and is supported .by' the side frames 88, 6|. Thus, any movement of the air cylinder 18 along rod 66 is accompanied by corresponding movement of the entire carriage as-V sembly and the record card carried thereby.

With the carriage and air cylinder at the extreme right, as shown, or in other words, in the iirst column position, the pump valve 5| is positioned in the normal position and the pump forcesv air through outlet 58, air line 62, hollow portion'of casting 63, air line 64, hollow portion of casting 65, hollow rod 68, a port 61 in rod 66, against a cylinder head 58 of cylinder 10, thus 'exerting pressure tending to move the carriage assembly toward the left. The hollow rod 66. which is divided near the center by a closure plug 68, may .be considered the piston for cylinder 10, and it will be noted that, whereas the usual piston and cylinder arrangement provides for movement of a piston within a stationary cylinder, here the piston -becomes the stationary element. It will be appreciated that while air 'is being forced from the pump along line 62 to exert pressure on the cylinder head 88, air in line 18 at the same time is being exhausted to create a. partial vacuum in line 19 which operates through the left half of piston rod'68 and its piston port 88 to provide, in effect, an additional force tending to move the air cylinder 10 to the left.

Normally overcoming the leftward bias of the cylinder 18 is an escapement assembly best shown in Fig. la. This assembly comprises a loosely pivoted, spring-biased dog 8| normally resting in a'tooth inthe rack 1|, and an escapement pawl 82 normally clear of the rack. A supporting bracket 83 carries a short shaft 84 on which is pivoted a rocker arm and the dog 8|. Arm 85 is biased in a. clockwise direction about shaft 84 by a spring 86 fastened to the supporting bracket 03.' 'I'he escapement pawl 02 is pivot' ally carried by an adjustable plate 81 (Fig. A1) fastened to the front of bracket 83. The rocker arm -85 is provided with a pin 88 which extends through a hole in the dog and another pin 88 which cooperates with a slot in ,the free end of the escapement pawl. A third pin 90 carried by the rocker arm is connected to an eye in a vertical rod 9|. The arrangement is such that downward movement of ro'd 9| rotates the rocker arm counterclockwise, causing pin 88 to raise the dog clear of the rack and pin 89 to lower the escapement pawl into a tooth in the Y rack. The rack is advanced a barely perceptible amount as the escapement pawl seats in a. tooth, and the dog is given a slight forward movement as the dog spring istakes up the slack at the pivot point of the dog. Upon restoration of rod 9|, the parts just described are returned to normal, except that the dog, by reason of its slight. linear displacement relative to the rack, seats The opening of scissors |02 permits a springv biased .bar |03 to move upwardly. The left end of bar |03 is formed into a hook portion |02 which engages with one of the blades of a reamer-shaped power actuator |05. The power actuator is in continuous clockwise rotation, as

viewed in Fig. 2, being secured to shaft 32. Thus, upon engagement of hook |00 with' one of the blades or power actuator |05, the bar |03 is moved quickly to the left. Bar |03 carries a pin |06 which engages the lower part of a bellcrank arm itil which in turn is pivoted on a v shaft |08 carried by the side frames of the machine. Thus, the leftward movement of bar |03 causes clockwise movement of bell-crank |07.`

Also pivoted on shaft |08 is a bail |02 which is set in clockwise rotation by the bell-crank arm |0'l. The bail mais connected with the escapement operating rod 0| and hence pulls the rod downward. The bar |02 is released from the power actuator |05 very shortly after its engagement; and the restoring spring H2 restores the bar and bell-crankml to normal, thus allowing bail |00 and rod 9| to be restored by spring te (Fig. la) to complete the operation of the escapement mechanism so as to advancethe carriage one column, .as described hereinbefore.

Attached to the bell-crank |01 is a connecting link i which connects with a smaller pivoted bell-crank member ||2 to rotate the latter meming the return of bell-crank |0`| to its normal position. Meanwhile, prior to the spacing of the carriage, a type bar |2| carrying type, denoting the character represented by theA key depressed,

is set in motion by suitable linkage, generally designated |22, which connects with, and receives its motion from,lbar |03 when the latter bar isl moved to the left. The movement of bar |03 is sudden and rapid so as to impart considerable momentum to the type bar to carry it up against the card with sufcient force'to'make an imprint. The card is backed by a suitable platen '|243 (Fig. 2) at the printing line which is immediately above the uppermost' punch. The printing and punching operations in themselves are conventional in machines of this type and consequently form no part of the present invention.

The operationsv of the machine thus far described have pertained tothe normal spacing movement of the carriage, by the escapement mechanism, which accompanies printing and punching. Now assume that it is desiredto skip the carriage from the column it happens to be in to a predetermined column to the left. 4This operation is commonly referred to as tabulating. An auxiliary rack |25 with columnar indications thereon is provided to facilitate this operation and is known as the tab rack. The tab" rack is connected to theA rest of the carriage assembly and moves therewith. A clip |20 is attached to rack |25 at a columnar position, one to the right of the position in which the rack is to stop at the end of a tabulating operation, which operation will now be described.

A tab key |30 (Fig. 9), which may be located infany convenient place on the machine, controls the initiation of a tabulating operation.

' Depression of key |30 closes contacts |3| to energize a solenoid |32 by an obvious circuit from positive line |33, wire |35, solenoid |32, contacts |3l, now closed, wire |30, contacts |37, contacts |30 to negative line |315. Solenoid |32, as may be seen from Fig. 3, is provided with a plunger |20 which connects with a lever ici pivotally secured to shaft |02. The latter shaftcarries a pair of arms |03 and |00, one of which, namely, |43 is connected to shaft |22 for rotation thereby and extends under the dog 8| and the other of which, namely, lili is loosely mounted on |42 and extends under an arm slidably carried by a portion of the frame of the machine. The arm |05 has a part |26 on it which extends outwardly toward the tab` rack but is normally beneath ber a limited amount, clockwise, upon operation of bell-crank |07. The lower part of bell-crank i2 is bent over to nt iny a slot'in one of the punches H5, the arrangement being such that upon operationof the bell-crank the punch is moved through the record card and a limited distance into ay die member |20. It should be mentioned at this point that, as the plmch is the withdrawal of the punch from the cara d'ur- 75 the rack sumciently .to permit clearance` for a clip such as |26. Energization of solenoid |32, however, has the edect of rocking shaft |42 to raise arm |62 and permits a spring |6611. (Fig. 2)

to raise arm |25. This lifts the dogi to release the rack and also ,lifts the arm |05 so that bent-over portion |20 on the end of the arm will be in position to engage the clip |26 on the tab rack when the carriage has moved the The arm |25 has considerable desired distance. play in its slidable mounting. so that it may be moved up and down an appreciable extent as (Fig. 1). AReferring for the moment to Fig. 1,

it will be noted that with the valve open, a portion of the air in hollowv casting 63 may pass into the pipes 18 and 18, thus tending to neutralize ,the partial vacuum in cylinder and to reduce the resultant force eiective on the cylinder. This effect is analogous to that of a governor on a spring-driven rack and. because of this feature, the carriage never attains an undesirably fast speed.

Maintenance of the tabulating solenoid |32 in its energized position during the entire tabulating operation is essential, because dog 8| must be kept out of the rack 1|. Therefore, a pair of holding contacts |55 (Figs. 3 and 9) are provided, these contacts being secured to side frame 60 in such a location as to be operated by the downward movement of lever |4| as the solenoid becomes energized. Contacts |55 close a holding circuit from positive line |33, wire |35, solenoid |32, wire |53, contacts |54, contacts |55 now closed, wire |36, contacts |31 and |39 to negative line |34.

The tabulating operation terminates as the clip |26 on the tab" rack strikes against the bent-over end |46 of the slidable arm |45, moving the arm to the left. Contacts |54, known as the tabulating solenoid break" contacts, are mounted so as to be opened by the leftward movement of arm |45 to open the holding circuit for solenoid |32 described above. A return spring |23 on the plunger |40 brings about the lowering of arms |43 and |44 as the solenoid is deenergized. Arm |45 then drops down below the clip |26, releasing the rack for movement, and the dog 8| seats itself into a tooth in the rack permitting the rack to move but one additional space. A spring '|41 (Fig. 3a) engaging the arm |45 returns the arm to its normal rightward position permitting contacts |54 to again close. Meanwhile, contacts |55 Vhave opened so that no circuit is completed to energize Splenoid |32 unless contacts |3| are again closed by the tab key |30.` As the solenoid plunger |40 is restored to normal by spring |23, lever |4| lowers valve stem |50 to place the valve once again in the normally closed position.

At certain times it is desirable to release the carriage immediately from whatever position it may be in and permit it to skip to the last column position. This operation is commonly referred to as ejecting, because after the carriage reaches the last column position the record card is ejected, as will be explained later. The actual movement of the carriage to the last column position is quite similar to that for the tabular skip operation described above. The tab solenoid |32 is energized to cause the dog 8| to be lifted off the rack 1| and to concurrently cause lever |4| to open the bleeder valve passageway |5|. There is one marked difference, however, between tabulating and ejecting, and that is in the provision of means effective during electing operations to prevent arm |45 from being raised to interfere with the tabular control clip |26. The means referred to comprise a solenoid |60. (Figs. 3 and 9) with an interposer |6| connected to the armature thereof. The solenoid is mounted on the frame of the machine to the right of arm |45. Energization of solenoid |60 causes interposer |6| (Fig. 3a) to extend over arm |45, thus holding arm |45 down even though the spring-driven arm |44 rendered operative by the energized solenoid |32 continues to urge arm |45 upward. An ejecting operation is initiated by the depression of a conveniently located key |65 (Fig. 9), which closes contacts |66 to establish a circuit for the purpose of energizing both the interposer solenoid |60 and the tabulating solenoid |32 as follows: positive line |33, wire |62, solenoid |60, relay winding |63, contacts |66, now closed, wire |64, contacts |38, to negative line |34. It will be noted that relay winding |63 is also energized by the, circuit just traced. This relay has three sets of contacts designated |68a, |63b, and |63c, respectively, which are changed from the position shown when the relay winding is energized. Thus, contacts |63a are now closed to provide a shunt circuit around contacts |66 to keep solenoid |60 and winding |63 energized. Contacts |631) are now closed to energize the tabulating solenoid |32, and contacts |63c are also now closed. for a purpose to be described presently.

A transfer contact assembly comprising contacts |31 and |38 (Figsrl and 9) is mounted on side frame 60 and is arranged to be operated by the leading edge of the air cylinder 10 as the carriage reaches the last column position. In the operated position, contacts |31 are opened and contacts |38 are closed. The tabulating solenoid |32 is deenergized by the opening of contacts |31, whereas a circuit is completed by the closure of contacts |38 through the already closed relay contacts |636. This circuit energizes a clutch solenoid |10 which is mounted on the framework of the machine at a point just to the left of the clutch shaft 25, as shown in Fig. 4. The armature |1| of solenoid |10 is connected with the lower end of an arm |12 whose upper end is pivoted to the frame at |18, Arm |12 carries a spring-biased, pivoted latching arm |14 which normally engages a dog |15 carryinga pawl |16. The pawl is aligned with a ratchet |11 fastened to the clutch shaft 25. With this construction, energization of the clutch solenoid |10 causes the dog |15 to be released from latcharm |14 so that pawl |16 engages ratchet |11. The dog |15 is connected with a .pair of cams |18 and |85a secured to shaft 25 and, consequently, engagement of the pawl with the ratchet cause the dog and the cams to rotate with the ratchet. A cam follower arm |13 is moved upwardlyas the cam |18 rotates. A pair of contacts mounted on the frame are closed by a pin |8| on the follower arm. The upper end of arm |19 raises a bar |28 and thus causes the card finger 13 to be rocked counterclockwise about its pivot 13a so as to remove the finger from the edge of the record card which has now entered the space between continuously running roller 29 and the idler roller 29a. As the second cam |650. rotates, a second cam follower |l pivoted on a stud |86, is rocked counterclockwise a limited amount to permit the spring-pressed roller 29a to move into engagement with the edge of the card, thereby squeezing the card between the rollers and causing its rapid ejection from the card carriage.

The next step in the cycle of operations is to effect a carriage return. In order to accomplish this, it is first necessary to energizethe pump solenoid 51 so as to shift the valve 5|, thereby reversing the direction of the effective air pressure on the air cylinder 10. Upon closure of contacts |80, as described above, a circuit is completed (Fig. 9) as follows: positive line |33, contacts |80 now closed, pump solenoid 51, contacts |63a also now closed, contacts |38 to negative line |34. Energization of the pump solenoid by 75 the circuit just traced causes closure of contacts |81 and .|88 by a pin |89 connected'tosolenoid i with rebound locking member |92 slidably sup-V dition the rebound locking member |92 to permit the carriage return. l,The reboundlocking member |92, asthe name implies, locks the carriage against righ'tward movement 'caused by rebound. The locking action is effected by a tilting of member |92 to bind against the rod |93. Solenoid |90, when energized, prevents member |92 from assuming its locking position so as to permit the carriage to be returned freely to its rightward limit of travel. It will be noted, that as the carriage moves back out of its last column position, contacts |31, previously opened, as described above, now close and the tabulating solenoid |32 becomes energized to open the bleeder valve and to raise the dog 8| to keep it from dragging .on the rack.

As the carriage reaches its extreme rightward position, it passes slightly beyond its true iirst column position and in .doing so engages the upper end of a lever |95, the lower end of which cooperates with contacts |39 to open these contacts and break all the existing circuits traced above. Thus, the pump valve 5| is restored to normal and the air pressure on cylinderV is reversed once more so as to tend to move the carriage to the left. Then, as the-carriage settles l back into-its true rst column position (dog 8| seating itself in the first column position of rack 1|), contacts |39 return to their normally closed open position soon enough to break the 'clutch solenoid circuit in time to allow the dog |15 to latch `up at the end of one revolution, and the left card iinger 13 and eject roller 29o-to be returned to normal.

In the foregoing description of ejecting and carriage return operations, it was assumed that the eject key |65 had been depressed. However, in the event that the carriage has been spaced to the last column asl a result of repeated punching operations, then the punching operation for initiates ejecting and carriage return operations through a special pair o f contacts 200 which are closed each time the bail |09 is operated,` but 1 which are only effective in the last column after contacts |38 close, as described above. 'Ihe circuit completed by contacts 200 is traceable from I positive line |33, wire |62, solenoid |60, relay coil,|63, wire 20|, contacts 200 now closed, wire 203, contacts |38 also now closed for the last v column position of the carriage, contacts |39, to

described hereinbcfore when the eject key |65v was depressed.v

While .there has been shown and described and pointed out the fundamental novel features of it will be understood that various omissions and substitutions and changes inthe form and details of the device illustrated and in its operation may be made by those skilled in the art without departing from the spirit of the invention. It is the intention therefore to be limited only as indicated by the scope of the following claims.

, What is claimed is:

1. In a machine of the class described, an airv system" including a Piston and a cylinder in cooperating ,relation, the piston being provided with ports permitting the passage of air to the cylinder from the piston and vice versa, an air pump connected in said system for normallyv forcing. air through said -piston and into the cylinder'to bias the cylinder in one direction with respect to the piston, carriage mechanism including a rack secured -to the cylinder and movable therewith as a unit, escapement mechanism normally cooperating with the rack to hold the cylinder` against movement in the biased direction, means for'operating the escapement mechanism to control the movement of the cylinder in said direction, and means actuated by said cylinder as said cylinder reaches its limit of travel in the said 'direction for reversing the direction of air pressure from said pump so as to force the cylinder back in the opposite direction, thereby automatically effecting return of the carriage to a predetermined position.

2. In a machine of the class described, an air system including anair cylinder slidably mounted on a hollow piston provided with ports permitting the passage of air of'the cylinder from the piston and viceversa, anlair pump connected in said system for normally forcing air through said piston and into the cylinder to bias the cylinder in one direction with respect to the piston,

carriage mechanism including a rack secured to 'i the cylinder and movable therewith as a "unit,

escapement mechanism normally. cooperating with the rack to hold the cylinder against movement in the biased direction, means for operating the escapement mechanism to control the movereversing the direction of air pressure from said lpump so as to force the cylinder back in the op-i posite direction to effect return of the carriage to a predetermined position.

3. In a machine of the class described, an air system including an air cylinder slidably mountthe last column of the record card automatically 55 ed on a hollow piston provided with ports permitting the passage of air to the cylinder from the piston and vice versa, an air pumpconnected in said system for normally forcing air through said piston and into the cylinder to bias the cylinder in one direction with respect to the piston, escapement mechanism operable to control limited movements of the cylinder in the biased direction, and means actuated by said cylinderafter a predetermined amount of movement in the said direction for reversing the direction of air pressure from said pump so as to force the cylinder back in the opposite direction to a predetermined position.

4. In a machine ofA the class described, an air system including an air cylinder slidably mounted on a hollow piston provided with ports per'- mitting the passage of air to the cylinder from the piston and vice versa, an air pump connected in said system for normally forcing air through the invention as applied tora single modification, 'l5 Said piston and into the cylinder to bias the cyl.-

inder away from a home position with respect to the piston, escapement mechanism operable to effect limited steps of movement of the cylinder in the biased direction, and means actuated by said cylinder after a predetermined amount of movement in the said direction for reversing the direction of air pressure from said pump so as to force the cylinder back to home position.

5. In a machine of the class described, an air system including a piston and a cylinder in cooperating relation, the piston being provided with ports permitting the `passage of air to the cylinder from the piston and vice versa, an air pump connected in said system for normally forcing air through said piston and into the cylinder t bias the cylinder away from a home position with 1 respect to the piston, escapement mechanism and means for operating the same to control the movement of the cylinder in the biased direction, means actuated by said cylinder after a predetermined amount of movement in the said direction for reversing the direction of air pressure from'said pump so as to force the cylinder back to the home position, and means actuated by the cylinder in arriving at the home position for reestablishing the normal bias of air pressure on the cylinder. a

6. In a machine of the class described, a hollow piston, a carriage assembly comprising a rack and an air cylinder secured together and mounted for slidable movement on said piston, an air pump having air line connections -with each end of the piston for normally forcing air through said piston in one direction and into said cylinder to bias the cylinder in said direction, escapement mechanism normally cooperating with the rack to hold the carriage assembly against movement in the biased direction and operable to permit normal spacing of said carriage in the said direction, tabular skip means operable to render the escapement mechanism ineiective, to cause the rack to be skipped a predetermined distanoy greater than the normal spacing distance, andmeans controlled by the last-mentioned means for partially neutralizing the air pressure on the cylinder during the tabular skipping operation to govern the speed of the carriage.

7, In a machine of the class described, a hollow piston, a carriage assembly comprising a rack and an air cylinder secured together and mounted for slidable movement on said piston, an air pump having air line connections with each end of the piston for normally forcing air through said piston in one direction and into the cylinder to bias said cylinder in said direction, escapement mechanism normally cooperating with the rack to hold the carriage against movement in the biased direction and operable to permit normal spacing of said carriage in said direction, tabular skip means operable to render the escapement mechanism ineliective, to cause the rack to be skipped a predetermined distance greater than the normal spacing distance, means controlled by the last-mentioned means for partially neutralizing the air pressure on the cylinder during the tabular skipping operation to govern the speed of the carriage, and means controlled by the carriage to restore the normal air pressure bias on the cylinder at the end of the skipping operation.

8. In a machine of the class described, a hollow piston, a carriage assembly comprising a rack and an air cylinder secured together and mounted for slidable movement on said piston; an air pump having air line connections with each end of said piston for normally establishing unequal air pressures at the ends of the piston to bias the cylinder in a predetermined direction with respect to said piston, escapement mechanism normally cooperating with the rack to hold the carriage against movement 1n the biased direction and operable to permit noi-mal spacing of said carriage in said direction, means for rendering the escapement mechanism ineffective and for causing the rack to be skipped a predetermined distance greater than the normal spacing distance, and means controlled by the last-mentioned means for partially equalizing the air pressures at the ends of the piston during the skipping operation to govern the speed of the carriage.

9. In a machine of the class described, a hollow piston, a carriage assembly comprising a rack and a hollow cylinder secured together and mounted for slidable movement on said piston, an air pump having connection with each end of said piston for normally establishing unequal air pressures at the ends of the piston to bias the cylinder in a predetermined directionwith respect to said piston, escapement mechanism and means for operating the same to cause normal spacing of the carriage in said direction,

tabular skipping means for superseding the escapement mechanism to cause the rack to be skipped a predetermined distance greater than the normal spacing distance, meanscontrolled by the last-mentioned means for partially equalizing the air pressures at the ends of the piston during the tabular skipping operation to govern the speed of the carriage, and means controlled by the carriage to restore the normal degree of inequality of air pressure at the ends of the piston.

10. In combination, a cylindrical element and a piston element cooperating therewith, one movable with respect to the other, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal air pressures on opposite sides of the movable element so as'to bias the latter element in one direction, escapement mechanism and means for operating the same to control the movement of the movable element in said direction, means actuated by said movable element after a predetermined amount of movement in the said direction for reversing the air line connections to cause movement of said element in the opposite direction to a predetermined position, and means actuated by the movable element at the latter position to change the air line connections so as to reestablish the normal bias on the movable element.

1l. In dombination, a cylindrical element and a piston element cooperating therewith, one movable with respect to the other, carriage mechanism includ-ing a rack secured to the movable element, an air pumpl air line connections between the pump and the elements in which the pump normally maintains unequal air pressures on opposite sides of the movable element so as to tend to move the latter element in one direction, an escapement mechanism cooperating with the rack to control the displacement of the movable element in said direction, means actuated by said movable element after a predetermined amount of movement in the said direction for reversing the air line connections to cause movement of said element in the opposite direction to return the carriage mechanism to a predeteranism including a rack secured to the movable element, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal airpressures on opposite sides of the movable elementso as to bias the latter element with a resultant force in one direction, an escapement mechanism cooperating with the rack to control the normal displacement of the lmovable element in the biased direction, means actuated by said movable element after a predetermined amount of movement in the said direction for reversing the air line connections to establish unequal air pressures providing a resultant force on the movable element in the opposite direction to return the carriage mechanism to a predetermined position, means eilective during the carriage return to partially neutralize the latter force by reducing the inequality of the air pressures to govern the speed of the carriage, and means actuated by the movable element at the predetermined position to change the air line connections to normal, thereby reestablishing the normal bias on the movableA element.

13. In combination, a cylindrical element and a piston element cooperating therewith, one movable with respect to the other, carriage mechanism including a rack secured to the movable element, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal air pressures at the ends of the movable element so as to bias the latter element with a resultant force in one direction, an escapement mechanism-cooperating with the rack to control the normal spacing of the movable element in the biased the escapement mechanism to skip the movable element directly to the'limit of its travel in the direction of the resultant force normallyvproduced by the unequal air pressures, means controlled by the eject means during the skipping of the movable element for partially neutralizing the eiect of the resultant force of the unequal air pressures to govern vthe speed of the movable element, and means actuated by said movable element upon reaching its limit of travel in said direction for reversing the direction of said resultant force to cause movement of said element in the opposite direction to return the carriage e spacing operations in the biased direction, skipping means for superseding the action of the esdirection, eject means superseding the effect of to be opened by the skipping means during ab-.

capement mechanism for greater than normal spacing, and a normally closed bleedervalve adapted to be opened by the skipping 1 means duringabnormal spacing operations and to partially neutralize the inequality of pressure on opposite sides of the movable element so as to gov-v ern the speed of the carriage.

15. 'In a machine of the class described, a piston element and a cylinder element, one movable with respect to the other, an air pump, a pair of air line connections between the pump and the normal spacing operations to partially neutralize the inequality of pressure on opposite sides of the movable element so as to prevent excessive speed of the caniage which would otherwise occur on the longer skipping operations.

1'6. In a machine of the class described, a piston element and a cylinder element,A one movable with respect to'the other, an air pump, a pair of air line connections between the pump and the elements, one at each end of said elements to establish unequal air pressures on the movable element so as to produce a resultant force for lbiasing said element in .a predetermined direc- I-tion, a carriage including a rack secured to the movable element, escapement mechanism cooperating with the rack for normal spacing operations in the biased direction,\skipping vmeans for superseding action of the escapement mechanism for greater than normal spacing, a normally closed bleeder valve connected between the air llines and adapted to be opened by the skipping means during the abnormal spacingof the carriage to partiallyneutralize the inequality of pressure on .opposite sides of the movable element so as to govern the speed of the carriage,

and means controlled by the movable element for automatically closing the bleeder valve at the end of abnormal spacing operations to reestablish the normal resultant force Afor biasing the` movable element in the predetermined direction in cooperation with the escapement mech-` anism. v

17. In a machine of the class described, a piston element and a cylinder element, one movable with respect to the other, an air pump, air line connections between the pump and said elements to establish unequal air pressures on opposite sides of the movable element and therebyto bias said element in one direction, a carriage including a rack secured to the movable element, f

escapement mechanism cooperating with the rack for normal spacing operations in the biased direction, skipping means for superseding the action of the escapement mechanism for greater than normal spacing, a normally closed-bleeder valve between said air line connections adapted normal spacing of the vcarriage to partiallyneutralize the inequality 'of pressure on opposite sides of the movable element so as to govern the speed of the carriage, and means for `effecting a reversal of said air line connections to etl'ect a return of the carriage after it has spaced a predetermined amount and for opening the bleeder valve automatically to pass air between the reversed air lineconnectionsto neutralize the resultant forceon the movable element during the carriage return.

18. In a machine of the class described, a cylinder element and a piston element cooperating therewith, one movable with respect to the other, a carriage secured to the movable element for movement therewith, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal pressures on opposite sides of vthe movable element so as to bias the latter element in one direction, an escapement mechanism normally operable to space the carriage in predetermined limited steps in the biased direction, means to render the escapement mechanism ineffective so as to cause the carriage to move freely in the said direction, pressure regulating means controlled by the last mentioned means to partially neutralize the inequality sides of the movable element to prevent excessive speed of the carriage during its free movement, and means controlled by the carriage as it reaches a predetermined point in its movement' for reversing the air line connections to cause movement of the carriage' in the reverse direction to a predetermined position and for actuating the pressure regulating means to govern the speed of the carriage during its return to said predetermined position.,

19. In a machine of the class described, a cylinder element and a piston element cooperating therewith, one movable with respect to the other, a carriage secured to the movable element for movement therewith, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal pressures on opposite sides of the movable element so as to bias the latter element in one direction, an escapement mechanism and means for operating the same to space the carriage normally in predetermined biased direction, ymeans to render the escapement mechanism ineffective so as to cause the carriage to move freely a greater than normal distance in the said direction, pressure regulating means controlled by the last-mentioned means during the free movement of the carriage to partially neutralize the inequality of pressure on opposite sides of the movable element to prevent excessive speed of the carriage, means controlled by the latter element at the end of its free movement to render the pressure regulatingmeans ineffective, and means controlled by the carriage, as it reaches the limit of its travel in the biased direction, for reversing the air line connections to cause movement of the carriage in the reverse direction to a predetermined position and for again actuating the pressure regulating means to govern the speed of the carriage during its return to said predetermined position.

20. In a machine of the class described, a cylinder element and a piston element in cooperating relation. the cylinder element being slidably mounted on the piston element. a carriage secured to the cylinder for'movement therewith as a unit, an air pump, air line connections between the pump and the elements in which the pump normally maintains unequal pressure on opposite sides of the head of the cylinder so as to bias the cylinder in one direction, an escapement mechanism and means normally operating the.

same to space the carriage in predetermined llmited steps in the biased direction, means to render the escapement mechanism4 ineffective so as to cause the carriageto move freely a greater than normal step in the said direction, air pressure regulating means controlled by the last-menlimited steps in the the pressure on opposite sides of the cylinder head to prevent excessive speed of said carriage,

of pressure 'on opposite means controlled by the carriage after it has completed its free movement to render the pressure regulating means ineiective and reestablish the normal air pressure bias on the cylinder head, and means controlled by the carriage after it has been spaced a predetermined amount in the biased direction for reversing the yair line connections to cause movement of the carriage in the reverse direction to a predetermined position and for again actuating the pressure regulating means to govern the speed of the carriage during its return to said predetermined position.

21. In a device of the character'described, a movable carriage, fluid means for moving said carriage, means for controlling said fluid means to produce a chosen sustained movement of said carriage, means rendered .effective upon operation of said controlling means to alter the effect oi' said fluid, and means controlled by said carriage and rendered eiective upon completion of said chosen sustained movement to restore said iluid means to normal.

22. In a device of the character described, a movable carriage, fluid means for moving said carriage, escapement mechanism for controlling the movement of said carriage, and means including a single operative device for both rendering said escapement mechanism inoperative and altering the eiect of said uid means.

23. In a device of the character described, a carriage, iluid means for moving said carriage in one direction, escapement means controlling the movement of said carriage in said one direction,

l means for rendering said escapement means inoperative and altering the degree of eect of said fluid means, and lmeans rendered operative upon a predetermined movement of said carriage in said direction to alter the directive effect of said fluid means to thereby reverse the movement of said carriage.

24. In a device of the character described,a movable carriage, uid means for moving said carriage in one direction, means rendered effective upon a predetermined movement in said one direction to reverse the effect of said uid means to thereby reverse the movement of said carriage, means eective during a sustained movement of said carriage in said one direction to alter the degree of eiect oi' said fluid means, means rendered efiective upon completion of said sustained movement to restore said iluid means to a normal degree of effectiveness, and means rendered eilective upon completion of said carriage reversal to restore the effect of said uid means to its normal direction of eilort.

25. In a device of the character described, a movable carriage, fluid" means for moving said carriage, means controlling the normal movement of said carriage under the inuence of said iluid means, means including means rendering said controlling means ineiective for producing an eject functional movement of said carriage and automatically altering the effect of said fluid said carriage, means rendered eiective upon movement of said carriage from the next to the last to the last intermittent position for automatically reversing theeiect of said fluid means said uid means to normal upon completion of said'skip movement, means for reversing the effect of said uid means upon movement of said carriage to a'predetermined position to thereby reverse the movement of said carriage, and means simultaneously altering the degree of eiectiveness of said uid means during said reversal.

28... In a device of the character described, a

movable carriage. uld-means forrmoving said carriage, means controlling said carriage to cause normal intermittent movement thereof, means for disabling said carriage controlling means to -cause sustained movement of said carriage, and means controlled by said disabling means to alter the eiect of said uid means. Y

29. In a device of the character described, a

movable carriage, fluid means for moving saidcarriage, means controlling said carriage to pro` .duce normal intermittent movement thereof, means including carriage `arresting means forproducing a tabulating movement of said carriage and altering the effect of said uid means', and means forproducing an eject movement of said carriage ycomprising means suppressing operation of said carriage arresting means during said ejection to prevent arresting of said carriage short of its eject position.

. ROBERT E. HART. 

